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Breakdown of the blood–brain barrier to proteins in white matter of the developing brain following systemic inflammation

Cell and Tissue Research volume 320pages 369–378 (2005)Cite this article

Abstract

Compromised blood–brain barrier permeability resulting from systemic inflammation has been implicated as a possible cause of brain damage in fetuses and newborns and may underlie white matter damage later in life. Rats at postnatal day (P) 0, P8 and P20 and opossums (Monodelphis domestica) at P15, P20, P35, P50 and P60 and adults of both species were injected intraperitoneally with 0.2–10 mg/kg body weight of 055:B5 lipopolysaccharide. An acute-phase response occurred in all animals. A change in the permeability of the blood–brain barrier to plasma proteins during a restricted period of postnatal development in both species was determined immunocytochemically by the presence of proteins surrounding cerebral blood vessels and in brain parenchyma. Blood vessels in white matter, but not grey matter, became transiently permeable to proteins between 10 and 24 h after lipopolysaccharide injection in P0 and P8 rats and P35–P60 opossums. Brains of Monodelphis younger than P35, rats older than P20 and adults of both species were not affected. Permeability of the blood–cerebrospinal fluid (CSF) barrier to proteins was not affected by systemic inflammation for at least 48 h after intraperitoneal injection of lipopolysaccharide. These results show that there is a restricted period in brain development when the blood–brain barrier, but not the blood–CSF barrier, to proteins is susceptible to systemic inflammation; this does not appear to be attributable to barrier “immaturity” but to its stage of development and only occurs in white matter.

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References

  • Abraham CS, Deli MA, Joo F, Megyeri P, Torpier G (1996) Intracarotid tumor necrosis factor-alpha administration increases the blood–brain barrier permeability in cerebral cortex of the newborn pig: quantitative aspects of double-labelling studies and confocal laser scanning analysis. Neurosci Lett 208:85–88

    Google Scholar 

  • Anthony DC, Bolton SJ, Fearn S, Perry VH (1997) Age-related effects of interleukin-1 beta on polymorphonuclear neutrophil-dependent increases in blood–brain barrier permeability in rats. Brain 120:435–444

    Google Scholar 

  • Bickel U, Grave B, Kang YS, Rey A del, Voigt K (1998) No increase in blood–brain barrier permeability after intraperitoneal injection of endotoxin in the rat. J Neuroimmunol 85:131–136

    Google Scholar 

  • Boje KM (1995) Cerebrovascular permeability changes during experimental meningitis in the rat. J Pharmacol Exp Ther 274:1199–1203

    Google Scholar 

  • Bradford MM (1976) A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Anal Biochem 72:248–254

    Google Scholar 

  • Brightman MW, Reese TS (1969) Junctions between intimately apposed cell membranes in the vertebrate brain. J Cell Biol 40:648–677

    Google Scholar 

  • Crowle AJ, Miller J (1981) Crossed immunoelectrophoresis of mouse serum. J Immunol Methods 43:15–28

    Google Scholar 

  • Dammann O, Leviton A (1997) Maternal intrauterine infection, cytokines, and brain damage in the preterm newborn. Pediatr Res 42:1–8

    Google Scholar 

  • Dammann O, Leviton A (2004) Inflammatory brain damage in preterm newborns—dry numbers, wet lab, and causal inferences. Early Hum Dev 79:1–15

    Google Scholar 

  • Davson H, Segal MB (1996) Physiology of the CSF and blood–brain barriers. CRC Press, Boca Raton

    Google Scholar 

  • Dziegielewska K, Evans CN, Malinowska DH, Møllgård K, Reynolds ML, Saunders NR (1980) Blood-cerebrospinal fluid transfer of plasma proteins during fetal development in the sheep. J Physiol (Lond) 300:457–465

    Google Scholar 

  • Dziegielewska KM, Evans CA, Lai PC, Lorscheider FL, Malinowska DH, Møllgård K, Saunders NR (1981) Proteins in cerebrospinal fluid and plasma of fetal rats during development. Dev Biol 83:193–200

    Google Scholar 

  • Dziegielewska KM, Habgood M, Jones SE, Reader M, Saunders NR (1989) Proteins in cerebrospinal fluid and plasma of postnatal Monodelphis domestica (grey short-tailed opossum). Comp Biochem Physiol [B] 92:569–576

    Google Scholar 

  • Dziegielewska KM, Habgood MD, Møllgård K, Stagaard M, Saunders NR (1991) Species-specific transfer of plasma albumin from blood into different cerebrospinal fluid compartments in the fetal sheep. J Physiol (Lond) 439:215–237

    Google Scholar 

  • Dziegielewska KM, Møller JE, Potter AM, Ek J, Lane MA, Saunders NR (2000) Acute phase cytokines, IL-1β and TNF-α in brain development. Cell Tissue Res 299:335–345

    Google Scholar 

  • Dziegielewska KM, Ek J, Habgood MD, Saunders NR (2001) Development of the choroid plexus. Invited review. Microsc Res Tech 52:5–20

    Google Scholar 

  • Ek CJ, Habgood MD, Dziegielewska KM, Potter A, Saunders NR (2001) Permeability and route of entry for lipid-insoluble molecules across brain barriers in developing Monodelphis domestica. J Physiol (Lond) 536:841–853

    Google Scholar 

  • Ek CJ, Habgood MD, Dziegielewska KM, Saunders NR (2003) Structural characteristics and barrier properties of the choroid plexuses in developing brain of the opossum (Monodelphis domestica). J Comp Neurol 460:451–464

    Google Scholar 

  • Ek CJ, Dziegielewska KM, Saunders NR (2004) Impermeability of cerebral blood vessels to small molecules in early brain development. Program no. 430.4 abstract viewer/itinerary planner. Society for Neuroscience, Washington, DC

    Google Scholar 

  • Felgenhauer K (1974) Protein size and cerebrospinal fluid composition. Klin Wochenschr 52:1158–1164

    Google Scholar 

  • Granger EM, Masterton RB, Glendenning KK (1985) Origin of interhemispheric fibers in acallosal opossum (with a comparison to callosal origins in rat). J Comp Neurol 241:82–98

    Google Scholar 

  • Habgood MD, Sedgwick JE, Dziegielewska KM, Saunders NR (1992) A developmentally regulated blood–cerebrospinal fluid transfer mechanism for albumin in immature rats. J Physiol (Lond) 456:181–192

    Google Scholar 

  • Hagberg H, Peebles D, Mallard C (2002) Models of white matter injury: comparison of infectious, hypoxic–ischemic, and excitotoxic insults. Ment Retard Dev Disabil Res Rev 8:30–38

    Google Scholar 

  • Huber JD, Witt KA, Hom S, Egleton RD, Mark KS, Davis TP (2001) Inflammatory pain alters blood–brain barrier permeability and tight junctional protein expression. Am J Physiol Heart Circ Physiol 280:H1241–H1248

    Google Scholar 

  • Kim WG, Mohney RP, Wilson B, Jeohn GH, Liu B, Hong JS (2000) Regional difference in susceptibility to lipopolysaccharide-induced neurotoxicity in the rat brain: role of microglia. J Neurosci 20:6309–6316

    Google Scholar 

  • Laurell JC (1965) Antigen–antibody crossed electrophoresis. Anal Biochem 10:358–361

    Google Scholar 

  • Mark KS, Miller DW (1999) Increased permeability of primary cultured brain microvessel endothelial cell monolayers following TNF-alpha exposure. Life Sci 64:1941–1953

    Google Scholar 

  • Mayhan WG (1998) Effect of lipopolysaccharide on the permeability and reactivity of the cerebral microcirculation: role of inducible nitric oxide synthase. Brain Res 792:353–357

    Google Scholar 

  • Mayhan WG (2000) Leukocyte adherence contributes to disruption of the blood–brain barrier during activation of mast cells. Brain Res 869:112–120

    Google Scholar 

  • Møllgård K, Malinowska DH, Saunders NR (1976) Lack of correlation between tight junction morphology and permeability properties in developing choroid plexus. Nature 264:293–294

    Google Scholar 

  • Navascués J, Cuadros MA, Almendros A (1996) Development of microglia: evidence from studies in the avian central nervous system. In: Ling EA, Tan CK, Tan CBC (eds) Topical issues in microglia research. Singapore Neuroscience Association, Singapore, pp 43–64

    Google Scholar 

  • Paxinos G, Tork I, Tecott LH, Valentino KL (1991) Developing rat brain. Academic Press, New York

    Google Scholar 

  • Quagliarello VJ, Wispelwey B, Long WJ Jr, Scheld WM (1991) Recombinant human interleukin-1 induces meningitis and blood–brain barrier injury in the rat. Characterization and comparison with tumor necrosis factor. J Clin Invest 87:1360–1366

    Google Scholar 

  • Rees S, Harding R (2004) Brain development during fetal life: influences of the intra-uterine environment. Neurosci Lett 361:111–114

    Google Scholar 

  • Reese TS, Karnovsky MJ (1967) Fine structural localization of a blood–brain barrier to exogenous peroxidase. J Cell Biol 34:207–217

    Google Scholar 

  • Richardson SJ, Dziegielewska KM, Andersen NA, Frost S, Schreiber G (1998) The acute phase response of plasma proteins in the polyprotodont marsupial Monodelphis domestica. Comp Biochem Physiol [B] 119:183–188

    Google Scholar 

  • Rothwell NJ (1999) Annual Review Prize Lecture. Cytokines—killers in the brain? J Physiol (Lond) 514:3–17

    Google Scholar 

  • Saija A, Princi P, Lanza M, Scalese M, Aramnejad E, De Sarro A (1995) Systemic cytokine administration can affect blood–brain barrier permeability in the rat. Life Sci 56:775–784

    Google Scholar 

  • Saukkonen K, Sande S, Cioffe C, Wolpe S, Sherry B, Cerami A, Tuomanen E (1990) The role of cytokines in the generation of inflammation and tissue damage in experimental gram-positive meningitis. J Exp Med 171:439–448

    Google Scholar 

  • Saunders N (1992) Ontogenic development of brain barrier mechanisms. In: Bradbury M (ed) Handbook of experimental pharmacology. Springer, Berlin Heidelberg New York, pp 327–369

    Google Scholar 

  • Saunders NR, Adam E, Reader M, Møllgård K (1989) Monodelphis domestica (grey short-tailed opossum): an accessible model for studies of early neocortical development. Anat Embryol (Berl) 180:227–236

    Google Scholar 

  • Saunders NR, Habgood MD, Dziegielewska KM (1999a) Barrier mechanisms in the brain, I. Adult brain. Clin Exp Pharmacol Physiol 26:11–19

    Google Scholar 

  • Saunders NR, Habgood MD, Dziegielewska KM (1999b) Barrier mechanisms in the brain. II. Immature brain. Clin Exp Pharmacol Physiol 26:85–91

    Google Scholar 

  • Schreiber G, Tyskin A, Aldred AR, Thomas T, Fung W-P, Dickson PW, Cole T, Birch H, De Jong FA, Millard J (1989) The acute phase response in the rodent. Ann N Y Acad Sci 557:61–83

    Google Scholar 

  • Shukla A, Dikshit M, Srimal RC (1995) Nitric oxide modulates blood–brain barrier permeability during infections with an inactivated bacterium. NeuroReport 6:1629–1632

    Google Scholar 

  • Swanson LW (1992) Brain maps: structure of the brain. Elsevier, Amsterdam

    Google Scholar 

  • Vries HE de, Blom-Roosemalen MC, Oosten M van, Boer AG de, Berkel TJ van, Breimer DD, Kuiper J (1996a) The influence of cytokines on the integrity of the blood–brain barrier in vitro. J Neuroimmunol 64:37–43

    Google Scholar 

  • Vries HE de, Blom-Roosemalen MC, Boer AG de, Berkel TJ van, Breimer DD, Kuiper J (1996b) Effect of endotoxin on permeability of bovine cerebral endothelial cell layers in vitro. J Pharmacol Exp Ther 277:1418–1423

    Google Scholar 

  • Weeke B (1973) Crossed immunoelectrophoresis. In: Axelsen NH, Kroll J, Weeke B (eds) A manual of quantitative immuno-electrophoresis. Universitetsforlaget, Oslo

    Google Scholar 

  • Wu CH, Wang HJ, Wen CY, Lien KC, Ling EA (1997) Response of amoeboid and ramified microglia cells to lipopolysaccharide injections in postnatal rats—a lectin and ultrastructural study. Neurosci Res 27:133–141

    Google Scholar 

  • Yan E, Castillo-Melendez M, Nicholls T, Hirst J, Walker D (2004) Cerebrovascular responses in the fetal sheep brain to low-dose endotoxin. Pediatr Res 55:855–863

    Google Scholar 

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Affiliations

  1. Department of Pharmacology, University of Melbourne, Parkville, Victoria, 3010, Australia

    H. B. Stolp, K. M. Dziegielewska, C. J. Ek, M. D. Habgood, M. A. Lane, A. M. Potter & N. R. Saunders

  2. Centre for Neuroscience, University of Melbourne, Parkville, Victoria, 3010, Australia

    N. R. Saunders

Authors
  1. H. B. Stolp
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  2. K. M. Dziegielewska
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  3. C. J. Ek
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  4. M. D. Habgood
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  5. M. A. Lane
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  6. A. M. Potter
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  7. N. R. Saunders
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Correspondence to N. R. Saunders.

Additional information

This work was supported by NIH grant number R01 NS043949-01A1.

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Stolp, H.B., Dziegielewska, K.M., Ek, C.J. et al. Breakdown of the blood–brain barrier to proteins in white matter of the developing brain following systemic inflammation. Cell Tissue Res 320, 369–378 (2005). https://doi.org/10.1007/s00441-005-1088-6

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  • DOI: https://doi.org/10.1007/s00441-005-1088-6

Keywords

  • Blood-brain barrier
  • Blood–CSF barrier
  • Cerebrospinal fluid
  • Acute-phase response
  • Lipopolysaccharide
  • Rat (Sprague Dawley)
  • South American opossum (Monodelphis domestica)